The scientific, educational and artistic endeavors of J. A. Panitz

Copyright ©2007-2008 J. A. Panitz. All Rights Reserved.

[107] J. A. Panitz. Microsc. Microanal. 14/2, 122-123 (2008).
Cryopreparation for Interfacial Atom-Probe Analysis.

[106] J. A. Panitz and Gertrude Rempfer. Am. J. Phys. 74, 953-956 (2006).
A transmission electron microscope for lecture demonstrations.

[105] J. A. Panitz. Microsc. Microanal. 11/2, 92-93 (2005).
In search of the chimera-molecular imaging in the atom-probe.

[104] J.A. Panitz. Am. J. Phys. 70, 280-284 (2002).
Contemporary electronics-a focussed concept laboratory.

[103] P.R. Schwoebel, et. al. J. Vac. Sci. Technol. B19, 980-987 (2001).
Field emission current cleaning and annealing of microfabricated cold cathodes.

[102] P.R. Schwoebel, et. al. J. Vac. Sci. Technol. B19, 582-584 (2001).
Emission uniformity enhancement between microfabricated tips in cold cathode arrays.

[101] M. K. Miller and J. A. Panitz. Microscopy and Microanalysis. 6, 1190-1191 (2000).
Microscopy Milestones-Field Ion Microscopy, Atom Probe Field Ion Microscopy and Atom Probe Tomography.

[100] P. R. Schwoebel, et. al. J. Vac. Sci. Technol. B18, 2579-2582 (2000).
In situ cleaning of microfabricated field emitter cathodes.

[99] G. R. Condon and J. A. Panitz. J. Vac. Sci. Technol. B18, 1216-1221 (2000).
Mapping the field-emission tunneling barrier of organic adsorbates on tungsten.

[98] T. Olson, et. al. J. Appl. Phys. 87, 2031-2038 (2000).
Analysis of bistable noise from microfabricated field emission cathodes.

[97] J. A. Panitz. The Archetypal Atom-Probe. Mater. Charact. 44, 3-10 (2000).

[96] R. T. Olson and J. A. Panitz. J. Vac Sci. Technol. B17, 2483-2487 (1999).
Direct current and pulsed operation of contaminated liquid metal ion sources.

[95] R. T. Olson and J. A. Panitz. Rev. Sci. Instrum. 69, 2067-2071 (1998).
An instrument for investigating high electric field phenomena at small electrode separations.

[94] J. A. Panitz. Microscopy and Microanalysis. 4 (Supplement 2), 74-75 (1998).
Anecdotes from an atom-probe original.

[93] G. R. Condon and J. A. Panitz. J. Vac. Sci. and Technol. B16, 23-29 (1998).
Nanoscale imaging of the electronic tunneling barrier at a metal surface.

[92] R. Sebring, et. al. Scanning Microscopy ‘97. (Chicago, IL. May 1997).
Structural characterization and comparison of iridium, platinum and gold/palladium ultra-thin film coatings for STM of biomolecules.

[91] M. E. Cox and J. A. Panitz. J. Vac. Sci. and Technol. A14, 1-2 (1996).
Filament Replacement for "nude" Bayard-Alpert Ion Gauges.

[90] J. A. Panitz. Microscopy and Microanalysis 1995 Ed. G.W. Bailey, M.H. Ellisman, R.A. Hennigar and N.J. Zaluzec (Jones and Begell, NY 1995) 676.
Atom-probe analysis of the solid-liquid interface.

[89] A. Stintz and J. A. Panitz. J. Vac. Sci. and Technol. A13, 169 (1995).
Field desorption of lithium fluoride.

[88] J. A. Panitz. Proc. 52nd Annual Meeting of the Microscope Society of America. G.W. Bailey and A.J. Garratt-Reed (San Francisco Press, CA 1994) 824.
Prospects for atom-probe analysis in biology and medicine.

[87] J. A. Panitz. J. Vac. Sci. and Technol. B12, 2889-2893 (1994).
Electrostatic removal of lithium fluoride from field-emitter tips at elevated temperatures.

[86] Mark Blount and J. A. Panitz. Appl. Phys. Letts. 64, 2175-2177 (1994).
Temporal response of a lithium nitrate electrohydrodynamic ion source.

[85] A. Stintz and J. A. Panitz. Int. J. Mass Spec. Ion Proc. 133, 59-64 (1994).
Negative cluster ion formation from water ice in high electric fields.

[84] A. Stintz and J. A. Panitz. Surface Science 296, 75-86 (1993).
Cluster ion formation in isothermal ramped field-desorption of amorphous water ice from metal surfaces.

[83] A. Stintz and J. A. Panitz. J. Appl. Phys. 72, 741-745 (1992).
Isothermal ramped field-desorption of water from metal surfaces.

[82] P.R. Schwoebel and J. A. Panitz. J. Appl. Phys. 71, 2151-2154 (1992).
The behavior of LiF-coated metal anodes in pulsed electric fields.

[81] P. R. Schwoebel and J. A. Panitz. Phys. Rev. Letts. 67, 2175-2178 (1991).
Ion emission from Liquid Lithium for Inertial Confinement Fusion Applications

[80] Andreas Stintz and J. A. Panitz. J. Vac. Sci. Technol. A9, 1365-1367 (1991).
Imaging atom-probe analysis of an aqueous interface.

[79] Andreas Stintz and J. A. Panitz. Surface Science 246, 163-168 (1991).
Imaging atom-probe analysis of a vitreous ice interface.

[78] J. A. Panitz. The Cellular and Molecular Biology of Pattern Formation. Ed. D. L. Stocum and T. L. Karr, (Oxford, NY 1990) 168-183.
Scanning Tunneling Microscopy: Status and Prospects for Imaging Biological Structure on an Atomic Scale.

[77] A. L. Pregenzer, K. W. Bieg, R. E. Olson and J. A. Panitz. J. Appl. Phys. 67, 7556-7559 (1990).
Ion production from LiF-coated field emitter tips.

[76] J. A. Panitz. Microbeam Analysis-1989. Ed: P. E. Russell. (San Francisco Press, CA 1989) 531-534.
STM Imaging of Biological Structure: Status and Prospects.

[75] R. García, et. al. Ultramicroscopy. 27, 367-374 (1989).
Imaging of metal-coated biological samples by scanning tunneling microscopy.

[74] J. A. Panitz. J. Vac. Sci. Technol. A7, 2850-2853 (1989).
Vitreous ice as a cryoprotectant for imaging atom-probe studies of adsorption phenomena at a solid-liquid interface.

[73] J. A. Panitz, A. L. Pregenzer and R. A. Gerber. J. Physique. 49/C6, 175-176 (1988).
Electrohydrodynamic Ion Emission for Inertial Confinement Fusion Applications.

[72] J. A. Panitz. EMSA46: Proceedings of the 46th annual meeting of the Electron Microscope Society of America. Ed: G.W. Bailey. (San Francisco Press, CA 1988) 440-441.
Point Projection Imaging of Biological Objects.

[71] J. A. Panitz, et. al. J. Vac. Sci. Technol. A7, 64-68 (1988).
Electrohydrodynamic ion emission from molten lithium nitrate.

[70] R. W. Stinnett, R. E. Olson, J. O. Dritt, K. W. Bieg, R. A. Gerber, P. F. McKay, J. A. Panitz, A. L. Pregenzer and J. R. Woodworth. Proceedings of the 12th International Symposium on Discharges and Electrical Insulation. (Paris, France, June 27-30, 1988).
Field-enhanced lithium ion sources for PBFA II.

[69] J. A. Panitz and J. J. Hren. J. Vac. Sci. Technol. A5, 1032-1035 (1987).
Surface imaging by carbon monoxide field desorption.

[68] J. A. Panitz. EMSA45: Proceedings of the 45th annual meeting of the Electron Microscope Society of America. Ed: G.W. Bailey. (San Francisco Press, CA 1987) 140-141.
A TEM Study of Electron tunneling in biological macromolecules.

[67] J. A. Panitz. Proteins at Interfaces: Physicochemical and biochemical studies. Ed: J. L. Brash and B. D. Ratner. (American Chemical Society Press, Washington, DC 1987) 422-433.
Electron Tunneling used as a probe of protein adsorption at interfaces.

[66] J. A. Panitz. Abstracts of the 61st ACS Colloid and Surf. Sci. Symposium. The University of Michigan (June 21-24 (1987)
Electron tunneling: a study of biological adsorption at an interface.

[65] J. A. Panitz. Microbeam Analysis-1986. Ed: A. D. Romig and W. F. Chambers. (San Francisco Press, CA 1986) 196-198.
Field-ion tomography.

[64] J. A. Panitz. EMSA44: Proceedings of the 44th Annual Meeting of the Electron Microscope Society of America. (San Francisco Press, CA 1986) 188-189.
Edge-projection tomography.

[63] J. A. Panitz and D. H. Sandison. J. Physique. 47/C2, 401-407 (1986).
Protein removal from tungsten field-emitter tips.

[62] J. A. Panitz. Methods of Experimental Physics. 22, Ed. R. L. Park and M. Lagally, (Academic Press, NY l985) 349-423.
High field techniques.

[61] J. A. Panitz and D. G. Bear. J. Microscopy (GB) 138, 107-110 (1985).
A procedure for increasing the contrast of biological specimens in edge-projection TEM.

[60] J. A. Panitz. Proceedings of the Fourth Pfefferkorn Conf. In: Science of Biological Specimen Preparation. (SEM Inc. Chicago, O’Hare 1985) 283-288.
The morphology of thin metal coatings formed by rotary shadowing biological species in high vacuum.

[59] J. A. Panitz. Rev. Sci. Instrum. 56, 572-574 (1985).
Biomolecular deposition on multiple field-emitter tips.

[58] J. A. Panitz, et. al. J. Elect. Micros. Techn. 2, 285-292 (1985).
A Deposition Technique for the Imaging and Analysis of Protein Interactions With Metal and Semiconductor Surfaces.

[57] J. A. Panitz. J. Coll. Interf. Sci. 111, 516-528 (1985).
Immunological layer formation on metal microelectrodes

[56] J. A. Panitz. J. Physique. 45 C9, 285-291 (1984).
Biomolecular adsorption and the LIFE detector.

[55] J. A. Panitz and G. L. Fowler. Rev. Sci. Instrum. 55, 1507-1508 (1984).
Retractable capillary doser

[54] J. A. Panitz. J. Appl. Phys. 56, 3319-3323 (1984).
Field-electron emission microscopy as a probe of biomolecular adsorption from solution.

[53] J. A. Panitz. Ultramicroscopy, 11, 161-166 (1983).
Direct visualization of unstained nucleic acids on a metal substrate.

[52] J. A. Panitz. The Analysis of Organic and Biological Surfaces. ed. P. Echlin (John Wiley & Sons, NY 1984) 171-190.
Point-projection microscopy.

[51] J. A. Panitz. Proceedings of the 29th International Field Emission Symposium. ed. H. Norden and H. O. Andren (Almquist and Wiksell, Stockholm, 1982) 249-255.
On the feasibility of imaging unstained DNA by field-ion tomography.

[50] J. A. Panitz and G. L. Fowler. Proceedings of the 29th International Field Emission Symposium. (Göteborg, Sweden 1982) 38.
Point-projection imaging of individual ferritin molecules on metallic substrates.

[49] J. A. Panitz. J. Phys. E. (Sci. Instrum). 15 1281-1294 (l982).
Field-ion microscopy-a review of basic principles and selected applications

[48] J. A. Panitz and D. C. Ghiglia. J. Microsc. (GB) 127, 259-264 (1982).
Point-projection imaging of unstained ferritin molecules on tungsten.

[47] J. A. Panitz. J. Vac. Sci. Technol. A20, 895 (1982).
Abstract: Ferritin deposition on tungsten and its desorption in a high electric field.

[46] J. A. Panitz. Ultramicroscopy, 7, 241-247 (1982).
Point-projection imaging of unstained ferritin clusters.

[45] J. A. Panitz. J. Microsc. (GB) 125, 3-23 (1982).
Point-projection imaging of macromolecular contours.

[44] J. A. Panitz. Proceedings of the 39th annual meeting of the Electron Microscope Society of America. Ed: G.W. Bailey (Claitor, Baton Rouge, LA 1981) 18-21.
Molecular imaging in high electric fields.

[43] J. A. Panitz and G. L. Fowler. Proceedings of the 28th International Field Emission Symposium. (Beaverton, OR 1981) 126.
Molecular imaging in high electric fields.

[42] J. A. Panitz and I. Giaever. Ultramicroscopy 6, 3-6 (1981).
Ferritin Deposition on field-emitter tips.

[41] J. A. Panitz and I. Giaever. Surface Science. 39, 25-42 (1980).
Protein deposition on field-emitter tips and its removal by UV radiation.

[40] J. A. Panitz and G. L. Fowler. Sci. Instrum. 51, 1730-1731 (1980).
Adapting a displex closed-cycle helium refrigerator for UHV operation.

[39] J. A. Panitz, et. al. Rev. Sci. Instrum. 51, 1267-1268 (1980).
Low-drift optical-densitometer.

[38] J. A. Panitz. J. Vac. Sci. Technol. 17, 757 (1980).
Video recording of low intensity CEMA images.

[37] J. A. Panitz and G. L. Kellogg. J. of Nucl. Matls. 85/86, 951-955 (1979).
Field desorption and field-ion surface studies of samples exposed to the plasmas of PLT and ISX.

[36] J. A. Panitz. Proceedings of the Workshop on the Analysis of Hydrogen in Solids. NTIS #DOE-ER-0026 (Sandia National Laboratories, Albuquerque, NM 1979) 53-63.
Imaging atom-probe and field ion investigations of hydrogen in metals.

[35] J. A. Panitz. J. Vac. Sci. Technol. A 16, 868-874 (1979).
Isothermal ramped field-desorption of benzene from tungsten.

[34] J. A. Panitz. J. Vac. Sci. Technol. A 16, 553 (1979).
Abstract: Isothermal ramped field-desorption of benzene from tungsten

[33] J. A. Panitz. Abstracts of the 25th International Field Emission Symposium. (Ultramicroscopy 4, 1979 p. 367).
Field-induced desorption of benzene from tungsten.

[32] J. A. Panitz and I. Giaever. Abstracts of the 25th International Field Emission Symposium. (Ultramicroscopy 4, 1979) p. 366.
Abstract-Low field desorption imaging of proteins.

[31] G. L. Kellogg and J. A. Panitz. Abstracts of the 25th International Field Emission Symposium. (Ultramicroscopy 4, 1979 p. 390).
Surface analysis of field-emitter samples exposed to the plasmas of PLT AND ISX.

[30] J. A. Panitz and G. L. Kellogg. Applications of Surface Science 3, 13-37 (1979).
The application of high-field surface analytical techniques to the study of plasma-wall interactions in PLT.

[29] J. A. Panitz. Progress in Surface Science 8, 219-262 (1978).
Imaging Atom-Probe Mass Spectroscopy,

[28] J. A. Panitz. J. of Vac. Sci. and Technol. A14, 502 (1977).
Deuterium depth profiles in metals using imaging field desorption.

[27] J. A. Panitz and R. J. Walko. Rev. of Sci. Instrum. 47, 125l-1254 (1976).
Determination of nanosecond high-voltage pulse shapes at the surface of needle emitters.

[26] J. A. Panitz. J. of Nucl. Matls. 63, 477-481 (1976).
Depth profiling a near surface carbon contaminant in implanted first wall materials.

[25] J. A. Panitz and J. A. Foesch. Rev. Sci. Instrum. 47, 44-49 (1976).
Areal detection efficiency of channel electron multiplier arrays.

[24] J. A. Panitz. SAND75-0315 (Sandia National Laboratories, Albuquerque, NM 1975).
Single atom mass spectroscopies: the atom-probe and imaging field-desorption mass spectrometer.

[23] J. A. Panitz. SAND75-0117 (Sandia National Laboratories, Albuquerque, NM 1975).
Time-of-flight calculation for paraxial ions field desorbed from sharp needle emitters.

[22] J. A. Panitz. SAND75-0116. (Sandia National Laboratories, Albuquerque, NM 1975).
A simplified calibration sequence for single-atom mass spectrometers.

[21] J. A. Panitz. CRC Critical Reviews in Solid State Sciences. 5, 153-178 (1975).
Surface characterization by single-atom mass spectroscopy.

[20] J. A. Panitz. J. Vac. Sci. Technol. 12, 210-212 (1975).
Field desorption of helium and neon from tungsten and iridium.

[19] J. A. Panitz. Proceedings of the the 21st International Field Emission Symposium. (Marseille, France 1974). p. 91.
Field desorption mass spectrometry of catalytic systems

[18] J. A. Panitz. Hydrogen Energy B, (Plenum, NY 1974) 1079-1087.
The crystallographic distribution of hydrogen on catalytic surfaces.

[17] J. A. Panitz. J. Appl. Phys. 45, 1112-1114 (1974).
Preflashover phenomena and electron-stimulated desorption in high electric fields.

[16] J. A. Panitz. J. Vac. Sci. Technol. A11, 206-210 (1974).
The crystallographic distribution of field-desorbed species.

[15] J. A. Panitz. Proceedings of the 1972 Conference on Electrical Insulation and Dielectric Phenomena (National Academy of Sciences, Washington, DC, 1973) 115.
Flashover surface spectrometry.

[14] J. A. Panitz. J. Vac. Sci. Technol. 10, 274 (1973).
Abstract-Preflashover Anode Ion Species in an Ultrahigh Vacuum Diode.

[13] J. A. Panitz. Rev. Sci. Instrum. 44, 1034-1038 (1973).
The 10-cm atom probe.

[12] J. A. Panitz. J. Appl. Phys. 44, 372-375 (1973).
Preflashover mass spectrometry.

[11] J. A. Panitz. Proceedings of the 5th International Conference on Discharges and Electrical Insulation in Vacuum. (Poznan, Poland 1972) 75.
Preflashover spectrometry of a vacuum diode.

[10] John A. Panitz. Rev. Sci. Instrum. 42, 724-725 (1971).
Wide aperture channel plate electron multipliers for mass spectrometer applications.

[9] John A. Panitz. The Atom Probe FIM (Ph.D. Thesis, 1969).

[8] John A. Panitz, S. Brooks McLane and Erwin W, Müler .
Rev. Sci. Instrum. 40, 1321-1324 (l969).
Calibration of the atom-probe FIM.

[7] Erwin W. Müller, S. B. McLane and J. A. Panitz. Surface Science. 17, 430 (1969).
Field adsorption and desorption of helium and neon.

[6] Erwin W. Müller, John A. Panitz and S. Brooks McLane.
Rev. Sci. Instrum. 39, 83-86 (1968).
The atom-probe field ion microscope.

[5] Erwin W. Müller, S. Brooks McLane and John A. Panitz. Proceedings of the 15th International Field Emission Symposium. (Bonn, West Germany, l968).
Abstract: A new atom probe FIM.

[4] Erwin W. Müller, S. Brooks McLane and John A. Panitz. Proceedings of the Fourth European Regional Conference on Electron Microscopy. (Rome, Italy l968) 135.
Abstract: An atom probe field ion microscope.

[3] Erwin W. Müller and John Panitz. Proceedings of the 14th International Field Emission Symposium. (National Bureau of Standards, Washington, DC 1967).
The atom-probe field ion microscope.

[2] John Panitz and Erwin W. Müller. Proceedings of the 13th International Field Emission Symposium. (Cornell University, Ithaca, NY l966).
Field Ion Microscopy of Beryllium.

[1] John A. Panitz. Field Ion Microscopy of Beryllium. (M.S. Thesis, 1966).